Compensated ensemble crystal oscillator for use in a well borehole system

Abstract

A compensated ensemble crystal oscillator clock system for use in a well borehohe system. The clock system includes preferably four quad compensated clocks, a compensated temperature sensor, and software for processing and correcting system response. Physical fabrication of elements of the quad compensated clocks, the compensated temperature sensor and cooperating software minimized drift in frequency of the oscillator clock system in harsh borehole environments encountered while drilling a borehole. The clock system exhibits a frequency stability of 2.8×10−9 or less over a temperature range of from 0° C. to 185° C. The compensated ensemble crystal oscillator clock system is particularly applicable to seismic-while-drilling operations wherein precise downhole measurements of time are required typically over a period of days.

Description

BACKGROUND OF THE INVENTION[0001]This invention is directed toward geophysical measurement apparatus and methods employed during the drilling of a well borehole. More specifically, the invention is directed toward a compensated ensemble crystal oscillator clock system that comprises a plurality of quad compensated clocks. Physical fabrication of elements of the oscillator ensemble and cooperating data processing software minimize drift in frequency of the oscillator clock system in harsh borehole environments encountered while drilling the borehole. The oscillator clock system is particularly applicable to seismic-while-drilling operations wherein precise downhole measurements of time are required typically over a period of days.[0002]Systems for measuring parameters within a well borehole, and geophysical parameters of earth formation in the vicinity of the well borehole, typically fall within two categorizes. The first category includes systems that measure parameters after the bo...

AI Technical Summary

Benefits of technology

[0006]The ensemble of quad compensated clocks provides the opportunity for the characteristics of each quad compensated clock to be observed with respect to other quad compensated clocks in the ensemble. Each quad compensated clock comprises an oscillator circuit that cooperates with four oscillator crystals configured as a quad compensated resonator. The ensemble preferably comprises a minimum of four quad compensated clocks. This embodiment of the system will be referred to as a “quad compensated ensemble crystal oscillator” or “QCEXO”. An ensemble of eight quad compensated clocks provides an extremely robust system, but additional manufacturing costs and subsequent operational and maintenance costs are incurred.

[0010]The QCEXO system is calibrated with an external reference during production, and subsequently with a reference at a well site prior to deployment. Long term performance, which may otherwise be impacted by changing frequency drifts and changing temperature coefficients, is improved considerably as a result of the QCEXO system cooperating with the calibration reference.

[0011]Each quad compensated clock in the ensemble is calibrated to an accurate external frequency reference at time of the initial system calibration. During this initial calibration, information such as an estimate of the profile of the frequency versus temperature dependence of each oscillator is input into the QCEXO system. It is preferred to subsequently “field” calibrate the QCEXO system to an external frequency reference available at the well site. The external frequency reference provides a calibration reference update for some of the system parameters. The QCEXO system has the ability to improve the knowledge of the characteristics of each of its members with time.

[0015]The QCEXO system exhibits a frequency stability of 2.8×10−9 or less over a temperature range of from 0° C. to 185° C. Furthermore, the QCEXO system minimizes adverse effects due to shock, vibration and general acceleration effects, inherent frequency inaccuracy, and lastly, oscillator frequency and time jumps, activity dips and drop outs which are categorically referred to as “abnormal behavior”. These performance characteristics are suited for SWD applications.

Problems solved by technology

An ensemble of eight quad compensated clocks provides an extremely robust system, but additional manufacturing costs and subsequent operational and maintenance costs are incurred.

The harsh borehole environment includes elevated and varying temperature, significant shock, oscillator aging and high vibration.

All of these factors degrade the accuracy and precision of any type of oscillator clock.

Such variations inherently limit the degree of compensation possible in single and dual resonator clock schemes as both the geometric alignment and the required amplitude drift from their calibration settings.

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